Cleavage of the Feline Calicivirus Capsid Precursor Is Mediated by a Virus-Encoded Proteinase

Feline calicivirus (FCV), a member of the Caliciviridae, produces its major structural protein as a precursor polyprotein from a subgenomic-sized mRNA. In this study, we show that the proteinase responsible for processing this precursor into the mature capsid protein is encoded by the viral genome at the 3′-terminal portion of open reading frame 1 (ORF1). Protein expression studies of either the entire or partial ORF1 indicate that the proteinase is active when expressed either in in vitro translation or in bacterial cells. Site-directed mutagenesis was used to characterize the proteinase Glu-Ala cleavage site in the capsid precursor, utilizing an in vitro cleavage assay in which mutant precursor proteins translated from cDNA clones were used as substrates for trans cleavage by the proteinase. In general, amino acid substitutions in the P1 position (Glu) of the cleavage site were less well tolerated by the proteinase than those in the P1′ position (Ala). The precursor cleavage site mutations were introduced into an infectious cDNA clone of the FCV genome, and transfection of RNA derived from these clones into feline kidney cells showed that efficient cleavage of the capsid precursor by the virus-encoded proteinase is a critical determinant in the growth of the virus.     

Re-visiting the functional Relevance of the highly conserved Serine 40 Residue within HIV-1 p6<Superscript>Gag</Superscript>

Background

HIV-1 formation is driven by the viral structural polyprotein Gag, which assembles at the plasma membrane into a hexagonal lattice. The C-terminal p6^Gag domain harbors short peptide motifs, called late domains, which recruit the cellular endosomal sorting complex required for transport and promote HIV-1 abscission from the plasma membrane. Similar to late domain containing proteins of other viruses, HIV-1 p6 is phosphorylated at multiple residues, including a highly conserved serine at position 40. Previously published studies showed that an S40F exchange in p6^Gag severely affected virus infectivity, while we had reported that mutation of all phosphorylatable residues in p6^Gag had only minor effects.

Findings

We introduced mutations into p6^Gag without affecting the overlapping pol reading frame by using an HIV-1 derivative where gag and pol are genetically uncoupled. HIV-1 derivatives with a conservative S40N or a non-conservative S40F exchange were produced. The S40F substitution severely affected virus maturation and infectivity as reported before, while the S40N exchange caused no functional defects and the variant was fully infectious in T-cell lines and primary T-cells.

Conclusions

An HIV-1 variant carrying a conservative S40N exchange in p6^Gag is fully functional in tissue culture demonstrating that neither S40 nor its phosphorylation are required for HIV-1 release and maturation. The phenotype of the S40F mutation appears to be caused by the bulky hydrophobic residue introduced into a flexible region.

     

Comprehensive Mutational Analysis Reveals p6Gag Phosphorylation To Be Dispensable for HIV-1 Morphogenesis and Replication

The structural polyprotein Gag of human immunodeficiency virus type 1 (HIV-1) is necessary and sufficient for formation of virus-like particles. Its C-terminal p6 domain harbors short peptide motifs that facilitate virus release from the plasma membrane and mediate incorporation of the viral Vpr protein. p6 has been shown to be the major viral phosphoprotein in HIV-1-infected cells and virions, but the sites and functional relevance of p6 phosphorylation are not clear. Here, we identified phosphorylation of several serine and threonine residues in p6 in purified virus preparations using mass spectrometry. Mutation of individual candidate phosphoacceptor residues had no detectable effect on virus assembly, release, and infectivity, however, suggesting that phosphorylation of single residues may not be functionally relevant. Therefore, a comprehensive mutational analysis was conducted changing all potentially phosphorylatable amino acids in p6, except for a threonine that is part of an essential peptide motif. To avoid confounding changes in the overlapping pol reading frame, mutagenesis was performed in a provirus with genetically uncoupled gag and pol reading frames. An HIV-1 derivative carrying 12 amino acid changes in its p6 region, abolishing all but one potential phosphoacceptor site, showed no impairment of Gag assembly and virus release and displayed only very subtle deficiencies in viral infectivity in T-cell lines and primary lymphocytes. All mutations were stable over 2 weeks of culture in primary cells. Based on these findings, we conclude that phosphorylation of p6 is dispensable for HIV-1 assembly, release, and infectivity in tissue culture.     

High-level expression of the HIV-1 Pr55gag polyprotein in transgenic tobacco chloroplasts

Plants have been recognized as a promising production platform for recombinant pharmaceutical proteins. The human immunodeficiency virus Gag (Pr55^gag) structural polyprotein precursor is a prime candidate for developing a HIV-1 vaccine, but, so far, has been expressed at very low level in plants. The aim of this study was to investigate factors potentially involved in Pr55^gag expression and increase protein yield in plant cells. In transient expression experiments in various subcellular compartments, the native Pr55^gag sequence could be expressed only in the chloroplast. Experiments with truncated subunits suggested a negative role of the 5′-end on the expression of the full gene in the cytosol. Stable transgenic plants were produced in tobacco by Agrobacterium-mediated nuclear transformation with protein targeted to plastids, and biolistic-mediated plastid transformation. Compared to the nuclear genome, the integration and expression of the gag transgene in the plastome resulted in significantly higher protein accumulation levels (up to 7–8% TSP, equivalent to 312–363 mg/kg FW). In transplastomic plants, a 25-fold higher protein accumulation was obtained by translationally fusing the Pr55^gag polyprotein to the N-terminus of the plastid photosynthetic RbcL protein. In chloroplasts, the Pr55^gag polyprotein was processed in a pattern similar to that achieved by the viral protease, the processing being more extended in older leaves of mature plants. The Gag proteins produced in transgenic plastids were able to assemble into particles resembling VLPs produced in baculovirus/insect cells and E. coli systems. These results indicate that plastid transformation is a promising tool for HIV antigen manufacturing in plant cells. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. IGV publication no. 330     

Fibronectin is a non-viral substrate for the HIV proteinase

The retrovirus encoded proteinase (PR) is required for the proper maturation of viral particles into infectious virus. The PR had been considered highly substrate specific, cleaving exclusively the viral gag and gag-pol protein precursor. It has recently been reported, however, that cytoskeleton and other cellular filament proteins can be cleaved by the HIV-1 PR. Here we have evidence that a cell-associated protein, the fibronectin (A-chain), is also cleaved in vitro specifically by this PR. The possibility of a cytotoxic role of the PR is conceivable.     

Human Immunodeficiency Virus Type 1 Protease Triggers a Myristoyl Switch That Modulates Membrane Binding of Pr55gag and p17MA

The human immunodeficiency virus type 1 (HIV-1) Pr55^gag gene product directs the assembly of virions at the inner surface of the cell plasma membrane. The specificity of plasma membrane binding by Pr55^gag is conferred by a combination of an N-terminal myristoyl moiety and a basic residue-rich domain. Although the myristate plus basic domain is also present in the p17MA proteolytic product formed upon Pr55^gag maturation, the ability of p17MA to bind to membranes is significantly reduced. It was previously reported that the reduced membrane binding of p17MA was due to sequestration of the myristate moiety by a myristoyl switch (W. Zhou and M. D. Resh, J. Virol. 70:8540–8548, 1996). Here we demonstrate directly that treatment of membrane-bound Pr55^gag in situ with HIV-1 protease generates p17MA, which is then released from the membrane. Pr55^gag was synthesized in reticulocyte lysates, bound to membranes, and incubated with purified HIV-1 protease. The p17MA product in the membrane-bound and soluble fractions was analyzed following proteolysis. Newly generated p17MA initially was membrane bound but then displayed a slow, time-dependent dissociation resulting in 65% solubilization. Residual p17MA could be extracted from the membranes with either high pH or high salt. Treatment of membranes from transfected COS-1 cells with protease revealed that Pr55^gag was present within sealed membrane vesicles and that the release of p17MA occurred only when detergent and salt were added. We present a model proposing that the HIV-1 protease is the “trigger” for a myristoyl switch mechanism that modulates the membrane associations of Pr55^gag and p17MA in virions and membranes.     

Analysis of the Assembly Function of the Human Immunodeficiency Virus Type 1 Gag Protein Nucleocapsid Domain

Previous studies have shown that in addition to its function in specific RNA encapsidation, the human immunodeficiency virus type 1 (HIV-1) nucleocapsid (NC) is required for efficient virus particle assembly. However, the mechanism by which NC facilitates the assembly process is not clearly established. Formally, NC could act by constraining the Pr55^gag polyprotein into an assembly-competent conformation or by masking residues which block the assembly process. Alternatively, the capacity of NC to bind RNA or make interprotein contacts might affect particle assembly. To examine its role in the assembly process, we replaced the NC domain in Pr55^gag with polypeptide domains of known function, and the chimeric proteins were analyzed for their abilities to direct the release of virus-like particles. Our results indicate that NC does not mask inhibitory domains and does not act passively, by simply providing a stable folded monomeric structure. However, replacement of NC by polypeptides which form interprotein contacts permitted efficient virus particle assembly and release, even when RNA was not detected in the particles. These results suggest that formation of interprotein contacts by NC is essential to the normal HIV-1 assembly process.Human immunodeficiency virus type 1 (HIV-1) encodes three major genes, gag, pol, and env, which are commonly found in all mammalian retroviruses. It also encodes accessory genes whose protein products are important for regulation of its life cycle (6, 30, 35). However, of all the genes encoded by HIV-1, only the protein product of the gag gene has been found to be necessary and sufficient for the assembly of virus-like particles (11, 13, 17, 22, 32, 33). The HIV-1 Gag protein initially is expressed as a 55-kDa polyprotein precursor (Pr55^gag), but during or shortly after particle release, Pr55^gag ordinarily is cleaved by the viral protease (PR). The products of the protease action are the four major viral proteins matrix (MA), capsid (CA), nucleocapsid (NC), and p6, and the two spacer polypeptides p2 and p1, which represent sequences between CA and NC and between NC and p6, respectively (15, 19, 23, 30).The HIV-1 nucleocapsid proteins have two Cys-X₂-Cys-X₄-His-X₄-Cys (Cys-His) motifs, reminiscent of the zinc finger motifs found in many DNA binding proteins, and NC has been shown to facilitate the specific encapsidation of HIV-1 genomic RNAs. In addition to its encapsidation function, NC influences virus particle assembly (7, 10, 17, 21, 40). In particular, Gag proteins lacking the NC domain fail to assemble virus particles efficiently. Nevertheless, some chimeric Gag proteins which carry foreign sequences in place of NC have been shown to assemble and release virus particles at wild-type (wt) levels (2, 37, 40). Thus, it appears that in some circumstances, the role that NC plays in virus particle assembly can be replaced. To date, it is not clear how NC affects particle assembly, although several possibilities might be envisioned. One possibility is that deletion of NC unmasks inhibitory sequences in p2 or the C terminus of CA. Alternatively, NC may simply provide a stable monomeric folded structure which locks CA or other Gag domains into an assembly-competent conformation. Another possibility is that NC facilitates assembly by forming essential protein-protein contacts between neighbor Pr^gag molecules, as suggested in cross-linking studies (21). Finally, the assembly role of NC may stem from its RNA binding capabilities, a hypothesis supported by studies of Campbell and Vogt (5), which have shown that RNA facilitates the in vitro assembly of retroviral Gag proteins into higher-order structures.To distinguish among possible mechanisms by which NC facilitates HIV-1 assembly, we replaced NC with polypeptides having known structural characteristics and examined particle assembly directed by these chimeric proteins. Using this approach, we have found that NC does not play a passive role in HIV-1 assembly as either a mask to assembly inhibitor domains or a nonspecific, stably folded structure. Rather, sequences known to form strong interprotein contacts were observed to enhance assembly, suggesting a similar role for the NC domain itself. With several assembly-competent chimeric proteins, we detected no particle-associated RNAs. These results suggest that while RNA may be essential to virus assembly in the context of the wt Pr55^gag protein, it is dispensable for formation of virus-like particles from chimeric proteins.     

TRIM5α associates with proteasomal subunits in cells while in complex with HIV-1 virions

Background

The HIV-1 p6 Gag protein regulates the final abscission step of nascent virions from the cell membrane by the action of two late assembly (L-) domains. Although p6 is located within one of the most polymorphic regions of the HIV-1 gag gene, the 52 amino acid peptide binds at least to two cellular budding factors (Tsg101 and ALIX), is a substrate for phosphorylation, ubiquitination, and sumoylation, and mediates the incorporation of the HIV-1 accessory protein Vpr into viral particles. As expected, known functional domains mostly overlap with several conserved residues in p6. In this study, we investigated the importance of the highly conserved serine residue at position 40, which until now has not been assigned to any known function of p6.

Results

Consistently with previous data, we found that mutation of Ser-40 has no effect on ALIX mediated rescue of HIV-1 L-domain mutants. However, the only feasible S40F mutation that preserves the overlapping pol open reading frame (ORF) reduces virus replication in T-cell lines and in human lymphocyte tissue cultivated ex vivo. Most intriguingly, L-domain mediated virus release is not dependent on the integrity of Ser-40. However, the S40F mutation significantly reduces the specific infectivity of released virions. Further, it was observed that mutation of Ser-40 selectively interferes with the cleavage between capsid (CA) and the spacer peptide SP1 in Gag, without affecting cleavage of other Gag products. This deficiency in processing of CA, in consequence, led to an irregular morphology of the virus core and the formation of an electron dense extra core structure. Moreover, the defects induced by the S40F mutation in p6 can be rescued by the A1V mutation in SP1 that generally enhances processing of the CA-SP1 cleavage site.

Conclusions

Overall, these data support a so far unrecognized function of p6 mediated by Ser-40 that occurs independently of the L-domain function, but selectively affects CA maturation and virus core formation, and consequently the infectivity of released virions.     

Uncoupling Human Immunodeficiency Virus Type 1 gag and pol Reading Frames: Role of the Transframe Protein p6* in Viral Replication

Apart from its regulatory role in protease (PR) activation, little is known about the function of the human immunodeficiency virus type 1 transframe protein p6* in the virus life cycle. p6* is located between the nucleocapsid and PR domains in the Gag-Pol polyprotein precursor and is cleaved by PR during viral maturation. We have recently reported that the central region of p6* can be extensively mutated without abolishing viral infectivity and replication in vitro. However, mutagenesis of the entire p6*-coding sequence in the proviral context is not feasible without affecting the superimposed frameshift signal or the overlapping p1-p6^gag sequences. To overcome these limitations, we created a novel NL4-3-derived provirus by displacing the original frameshift signal to the 3′ end of the gag gene, thereby uncoupling the p6* gene sequence from the p1-p6^gag reading frame. The resulting virus (AL) proved to be replication competent in different cell cultures and thus represents an elegant tool for detailed analysis of p6* function. Hence, extensive deletions or substitutions were introduced into the p6* gene sequence of the AL provirus, and effects on particle release, protein processing, and viral infectivity were evaluated. Interestingly, neither the deletion of 63% of all p6* residues nor the partial substitution by a heterologous sequence affected virus growth and infectivity, suggesting that p6* is widely dispensable for viral in vitro replication. However, the insertion of a larger reporter sequence interfered with virus production and maturation, implying that the length or conformation of this spacer region might be critical for p6* function.The transframe protein p6*, also referred to as TFP-p6^pol, is one of the least-characterized gene products in human immunodeficiency virus type 1 (HIV-1), consistently raising controversial discussions on its main function in the viral life cycle. p6* is located at the amino terminus of the Pol moiety within the Gag-Pol precursor, which is synthesized following a programmed ribosomal −1 frameshift during translation (Fig. ​(Fig.1).1). In contrast, the Gag precursor is generated by conventional translation at a 20-fold-higher rate (summarized in reference 13). The characterization of recombinant p6* protein by nuclear magnetic resonance analysis revealed a highly flexible structure (3), suggesting that p6* might serve as an adjustable hinge within the large Gag-Pol precursor to facilitate folding of the bulky protein domains during viral assembly. Proper folding of the embedded homodimeric protease (PR) is an essential prerequisite for full activity following sequential autocleavage from the full-length Gag-Pol polyprotein (summarized in reference 13). Indeed, the p6* residues have been demonstrated to stabilize the PR dimer and dictate the folding propensities of PR precursors, thereby influencing the rate of PR maturation (6, 10, 21). Interestingly, the autoprocessing of a truncated Gag-PR precursor was clearly accelerated when the p6* sequence was deleted, leading to the proposal that the active site of the PR might be less accessible in the presence of p6* (26). Further observations that p6* itself is sequentially cleaved by the PR (1, 7, 22, 23, 24, 30, 31, 32, 41) strengthened the hypothesis that the transframe protein contributes to spatiotemporal activation of the PR. Indeed, we and others have previously shown that the PR needs to be released from the flanking p6* residues to be capable of completing all virus-associated processing steps (24, 27, 36). The potential of p6* to regulate PR activity has been further corroborated by our finding that recombinant p6* protein comprising a free accessible carboxyl terminus is a potent inhibitor of the mature PR in vitro (28). Apart from the carboxyl-terminal tetrapeptide mainly contributing to the observed inhibition, the amino-terminal octapeptide of p6* (TFP) has been reported to inhibit PR activity in vitro (21).Open in a separate windowFIG. 1.Gag and Gag-Pol polyproteins encoded by NL4-3 (NL) and AL proviruses. (A) Schematic representation of the Gag and Gag-Pol polyprotein precursors. The p6* domain within Gag-Pol is highlighted in black, and the p1-p6^gag region inserted in the Gag-Pol precursor of AL is shaded gray; the five residues appended to p6^gag in Gag are indicated by a black vertical line. MA, matrix protein; NC, nucleocapsid protein; IN, integrase. (B) The Gag (gray) and Pol (black) products translated in the presence of the original frameshift site in NL are indicated on top, and the corresponding passage synthesized in AL after destruction of the slippery site is shown below. The active (NL) and inactive (AL) slippery sites are underlined, and the 3′ nucleotides contributing to the stem-loop structure are in parentheses. (C) An artificial frameshift site was introduced at the 3′ end of the gag gene in AL, resulting in the synthesis of a Gag-Pol polyprotein with p6* directly fused to p6^gag. The gag reading frame in AL is terminated by an artificial stop codon (boxed) and is extended by the residues ANFLG. The E₄→V₄ substitution in p6* is marked by a circle, and numbers at the left indicate amino acid positions within Gag and Gag-Pol with respect to the Gag start codon.The fact that p6* has a substantial size of 55 to 72 amino acids, depending on the isolate, raises the question of whether the transframe protein exerts other functions apart from PR regulation. In this regard, p6* has also been proposed to be a possible binding partner of the viral Nef protein, the major pathogenicity factor during HIV infection (9). However, the target site within p6* for Nef interaction has not been mapped so far.Although it is completely overlapped by the p1-p6^gag domains, the p6* sequence offers much room for natural polymorphisms (5). Furthermore, amino acid insertions or duplications, as well as deletions of up to 13 residues, in p6* sequences of infectious isolates have been reported, some of which are associated with viral drug resistance (4, 29, 35, 38). We have recently shown that nonconservative substitutions of up to 70% of the p6* residues in a provirus clone did not abolish viral growth or infectivity in various cell lines, suggesting that the central p6* region is widely dispensable for viral in vitro replication (19, 27).Unlike the variable center, the p6* amino terminus is highly conserved owing to the overlapping p1^gag sequence (14) and the RNA frameshift signal composed of a heptanucleotide slippery site (UUUUUUA) and a 3′ pseudoknot structure (11). This complex sequence context imposes major restrictions on mutational analysis of the p6* amino terminus in the viral background (24). To allow for a more in-depth functional analysis of the conserved p6* residues in the viral context, we have established a novel NL4-3-based provirus with p1-p6^gag and p6* reading frames uncoupled via a dislocated frameshift site. Thereby, we could demonstrate that neither the deletion of the bulk of p6* nor the insertion of a short unrelated sequence significantly affected replication and infectivity of the virus in different cell cultures. However, the insertion of a five times larger green fluorescent protein (GFP)-encoding sequence into the p6* reading frame was associated with a clear loss of particle production and infectivity. Therefore, we conclude that p6* is a spacer protein of limited length which is widely dispensable for viral replication in vitro.     

Patients Infected with CRF07_BC Have Significantly Lower Viral Loads than Patients with HIV-1 Subtype B: Mechanism and Impact on Disease Progression

The circulating recombinant form (CRF) 07_BC is the most prevalent HIV-1 strain among injection drug users (IDUs) in Taiwan. It contains a 7 amino-acid deletion in its p6^gag. We conducted a cohort study to compare viral loads and CD4 cell count changes between patients infected with subtype B and CRF07_BC and to elucidate its mechanism. Twenty-one patients infected with CRF07_BC and 59 patients with subtype B were selected from a cohort of 667 HIV-1/AIDS patients whom have been followed up for 3 years. Generalized estimated equation was used to analyze their clinical data and the results showed that patients infected with CRF07_BC had significantly lower viral loads (about 58,000 copies per ml less) than patients with subtype B infection (p = 0.002). The replicative capacity of nine CRF07_BC and four subtype B isolates were compared and the results showed that the former had significantly lower replicative capacity than the latter although all of them were CCR5- tropic and non-syncytium inducing viruses. An HIV-1-NL4-3 mutant virus which contains a 7 amino-acid deletion in p6^gag (designated as 7d virus) was generated and its live cycle was investigated. The results showed that 7d virus had significantly lower replication capacity, poorer protease-mediated processing and viral proteins production. Electron microscopic examination of cells infected with wild-type or 7d virus demonstrated that the 7d virus had poorer and slower viral maturation processes: more viruses attached to the cell membrane and higher proportion of immature virions outside the cells. The interaction between p6^gag and Alix protein was less efficient in cells infected with 7d virus. In conclusion, patients infected with CRF07_BC had significantly lower viral loads than patients infected with subtype B and it may due to the deletion of 7 amino acids which overlaps with Alix protein-binding domain of the p6^gag.     

HIV-1 Protease in the Fission Yeast Schizosaccharomyces pombe

Background

HIV-1 protease (PR) is an essential viral enzyme. Its primary function is to proteolyze the viral Gag-Pol polyprotein for production of viral enzymes and structural proteins and for maturation of infectious viral particles. Increasing evidence suggests that PR cleaves host cellular proteins. However, the nature of PR-host cellular protein interactions is elusive. This study aimed to develop a fission yeast (Schizosaccharomyces pombe) model system and to examine the possible interaction of HIV-1 PR with cellular proteins and its potential impact on cell proliferation and viability.

Results

A fission yeast strain RE294 was created that carried a single integrated copy of the PR gene in its chromosome. The PR gene was expressed using an inducible nmt1 promoter so that PR-specific effects could be measured. HIV-1 PR from this system cleaved the same indigenous viral p6/MA protein substrate as it does in natural HIV-1 infections. HIV-1 PR expression in fission yeast cells prevented cell proliferation and induced cellular oxidative stress and changes in mitochondrial morphology that led to cell death. Both these PR activities can be prevented by a PR-specific enzymatic inhibitor, indinavir, suggesting that PR-mediated proteolytic activities and cytotoxic effects resulted from enzymatic activities of HIV-1 PR. Through genome-wide screening, a serine/threonine kinase, Hhp2, was identified that suppresses HIV-1 PR-induced protease cleavage and cell death in fission yeast and in mammalian cells, where it prevented PR-induced apoptosis and cleavage of caspase-3 and caspase-8.

Conclusions

This is the first report to show that HIV-1 protease is functional as an enzyme in fission yeast, and that it behaves in a similar manner as it does in HIV-1 infection. HIV-1 PR-induced cell death in fission yeast could potentially be used as an endpoint for mechanistic studies, and this system could be used for developing a high-throughput system for drug screenings.     

Structural basis of the association of HIV-1 matrix protein with DNA

HIV-1 matrix (MA) is a multifunctional protein that is synthesized as a polyprotein that is cleaved by protease during viral maturation. MA contains a cluster of basic residues whose role is controversial. Proposed functions include membrane anchoring, facilitating viral assembly, and directing nuclear import of the viral DNA. Since MA has been reported to be a component of the preintegration complex (PIC), we have used NMR to probe its interaction with other PIC components. We show that MA interacts with DNA and this is likely sufficient to account for its association with the PIC.     

A p6Pol-protease fusion protein is present in mature particles of human immunodeficiency virus type 1.

Human immunodeficiency virus type 1 (HIV-1) protease (PR) and p6(Pol) are translated as part of the Gag-Pol polyprotein after a ribosomal frameshift. PR is essential to virus replication and is responsible for cleaving Gag and Gag-Pol precursors, but the role of p6(Pol) in HIV-1 infection is poorly understood. Here, we report that (i) PR is present in mature HIV-1 virions primarily as a p6(Pol)-PR fusion protein; (ii) HIV-1 PR cleaves viral precursor proteins expressed in bacterial cells at the Phe-Leu bond (positions 1639 to 1642) located at the junction of the NC and p6(Pol) proteins, releasing the p6(Pol)-PR fusion protein; and (iii) purified p6(Pol)-PR fusion protein undergoes autocleavage in vitro at at least three sites.     

Maturation of the Hepatitis A Virus Capsid Protein VP1 Is Not Dependent on Processing by the 3Cpro Proteinase

Most details of the processing of the hepatitis A virus (HAV) polyprotein are known. Unique among members of the family Picornaviridae, the primary cleavage of the HAV polyprotein is mediated by 3Cpro, the only proteinase known to be encoded by the virus, at the 2A/2B junction. All other cleavages of the polyprotein have been considered to be due to 3Cpro, although the precise location and mechanism responsible for the VP1/2A cleavage have been controversial. Here we present data that argue strongly against the involvement of the HAV 3Cpro proteinase in the maturation of VP1 from its VP1-2A precursor. Using a heterologous expression system based on recombinant vaccinia viruses directing the expression of full-length or truncated capsid protein precursors, we show that the C terminus of the mature VP1 capsid protein is located near residue 764 of the polyprotein. However, a proteolytically active HAV 3Cpro that was capable of directing both VP0/VP3 and VP3/VP1 cleavages in vaccinia virus-infected cells failed to process the VP1-2A precursor. Using site-directed mutagenesis of an infectious molecular clone of HAV, we modified potential VP1/2A cleavage sites that fit known 3Cpro recognition criteria and found that a substitution that ablates the presumed 3Cpro dipeptide recognition sequence at Glu764-Ser765 abolished neither infectivity nor normal VP1 maturation. Altered electrophoretic mobility of VP1 from a viable mutant virus with an Arg764 substitution indicated that this residue is present in VP1 and that the VP1/2A cleavage occurs downstream of this residue. These data indicate that maturation of the HAV VP1 capsid protein is not dependent on 3Cpro processing and may thus be uniquely dependent on a cellular proteinase.     

Structure of the N-terminal 283-residue fragment of the immature HIV-1 Gag polyprotein

The capsid protein (CA) of the mature human immunodeficiency virus (HIV) contains an N-terminal beta-hairpin that is essential for formation of the capsid core particle. CA is generated by proteolytic cleavage of the Gag precursor polyprotein during viral maturation. We have determined the NMR structure of a 283-residue N-terminal fragment of immature HIV-1 Gag (Gag(283)), which includes the intact matrix (MA) and N-terminal capsid (CA(N)) domains. The beta-hairpin is unfolded in Gag(283), consistent with the proposal that hairpin formation occurs subsequent to proteolytic cleavage of Gag, triggering capsid assembly. Comparison of the immature and mature CA(N) structures reveals that beta-hairpin formation induces a approximately 2 A displacement of helix 6 and a concomitant displacement of the cyclophylin-A (CypA)-binding loop, suggesting a possible allosteric mechanism for CypA-mediated destabilization of the capsid particle during infectivity.     

Nonreciprocal Packaging of Human Immunodeficiency Virus Type 1 and Type 2 RNA: a Possible Role for the p2 Domain of Gag in RNA Encapsidation

The ability of human immunodeficiency virus types 1 (HIV-1) and 2 (HIV-2) to cross-package each other’s RNA was investigated by cotransfecting helper virus constructs with vectors derived from both viruses from which the gag and pol sequences had been removed. HIV-1 was able to package both HIV-1 and HIV-2 vector RNA. The unspliced HIV-1 vector RNA was packaged preferentially over spliced RNA; however, unspliced and spliced HIV-2 vector RNA were packaged in proportion to their cytoplasmic concentrations. The HIV-2 helper virus was unable to package the HIV-1 vector RNA, indicating a nonreciprocal RNA packaging relationship between these two lentiviruses. Chimeric proviruses based on HIV-2 were constructed to identify the regions of the HIV-1 Gag protein conferring RNA-packaging specificity for the HIV-1 packaging signal. Two chimeric viruses were constructed in which domains within the HIV-2 gag gene were replaced by the corresponding domains in HIV-1, and the ability of the chimeric proviruses to encapsidate an HIV-1-based vector was studied. Wild-type HIV-2 was unable to package the HIV-1-based vector; however, replacement of the HIV-2 nucleocapsid by that of HIV-1 generated a virus with normal protein processing which could package the HIV-1-based vector. The chimeric viruses retained the ability to package HIV-2 genomic RNA, providing further evidence for a lack of reciprocity in RNA-packaging ability between the HIV-1 and HIV-2 nucleocapsid proteins. Inclusion of the p2 domain of HIV-1 Gag in the chimera significantly enhanced packaging.     

Residual HIV-1 DNA Flap-independent nuclear import of cPPT/CTS double mutant viruses does not support spreading infection

Background

Bevirimat, the prototype Human Immunodeficiency Virus type 1 (HIV-1) maturation inhibitor, is highly potent in cell culture and efficacious in HIV-1 infected patients. In contrast to inhibitors that target the active site of the viral protease, bevirimat specifically inhibits a single cleavage event, the final processing step for the Gag precursor where p25 (CA-SP1) is cleaved to p24 (CA) and SP1.

Results

In this study, photoaffinity analogs of bevirimat and mass spectrometry were employed to map the binding site of bevirimat to Gag within immature virus-like particles. Bevirimat analogs were found to crosslink to sequences overlapping, or proximal to, the CA-SP1 cleavage site, consistent with previous biochemical data on the effect of bevirimat on Gag processing and with genetic data from resistance mutations, in a region predicted by NMR and mutational studies to have α-helical character. Unexpectedly, a second region of interaction was found within the Major Homology Region (MHR). Extensive prior genetic evidence suggests that the MHR is critical for virus assembly.

Conclusions

This is the first demonstration of a direct interaction between the maturation inhibitor, bevirimat, and its target, Gag. Information gained from this study sheds light on the mechanisms by which the virus develops resistance to this class of drug and may aid in the design of next-generation maturation inhibitors.     

Protease Cleavage Leads to Formation of Mature Trimer Interface in HIV-1 Capsid

During retrovirus particle maturation, the assembled Gag polyprotein is cleaved by the viral protease into matrix (MA), capsid (CA), and nucleocapsid (NC) proteins. To form the mature viral capsid, CA rearranges, resulting in a lattice composed of hexameric and pentameric CA units. Recent structural studies of assembled HIV-1 CA revealed several inter-subunit interfaces in the capsid lattice, including a three-fold interhexamer interface that is critical for proper capsid stability. Although a general architecture of immature particles has been provided by cryo-electron tomographic studies, the structural details of the immature particle and the maturation pathway remain unknown. Here, we used cryo-electron microscopy (cryoEM) to determine the structure of tubular assemblies of the HIV-1 CA-SP1-NC protein. Relative to the mature assembled CA structure, we observed a marked conformational difference in the position of the CA-CTD relative to the NTD in the CA-SP1-NC assembly, involving the flexible hinge connecting the two domains. This difference was verified via engineered disulfide crosslinking, revealing that inter-hexamer contacts, in particular those at the pseudo three-fold axis, are altered in the CA-SP1-NC assemblies compared to the CA assemblies. Results from crosslinking analyses of mature and immature HIV-1 particles containing the same Cys substitutions in the Gag protein are consistent with these findings. We further show that cleavage of preassembled CA-SP1-NC by HIV-1 protease in vitro leads to release of SP1 and NC without disassembly of the lattice. Collectively, our results indicate that the proteolytic cleavage of Gag leads to a structural reorganization of the polypeptide and creates the three-fold interhexamer interface, important for the formation of infectious HIV-1 particles.